KR20180022812A - Multifunction tray - Google Patents

Abstract

Multifunction trays can be used in a variety of applications to form different products such as planter boards for green roofing, insulating structures for roof deck insulation, solid concrete panels for building construction, and the like. The tray includes a top portion, a bottom portion, and a backing layer connected between the top portion and the bottom portion. The lower portion includes a plurality of storage portions having through-holes. The upper part has a plurality of partitions and a fixed unit for fixing the material in the upper part.

Description

Multifunction tray

The present invention is applicable to a wide variety of products to form different products such as planter boards for green roof plantations, adiabatic structures for roof deck insulation, solid concrete panels for building construction, To multifunctional trays that can be used in applications.

In building construction, temporary moldings are often used to cast concrete into the desired shape. Once the concrete is cured, the mold will be removed. For example, a mold can be used to form a solid concrete panel that is generally suitable for lightweight, robust and low-cost mass housing plans. In green loop applications, a planter board is often used to accommodate planting media and plant material. These planter boards generally have a small reservoir to assist in storing or draining water. In roof deck insulation applications, temporary moldings are often used to mold insulating panels. Once the panel is cured, the mold will be removed.

Each of the above prior art die and planter boards as well as other prior arts has been designed to be used only in certain applications and not in other ways. For example, a planter board is always designed to be used only to grow plant material and not to be used to cast cement panels for building construction. Similarly, molds designed to be used for casting insulating panels are not suitable for use in growing plant material in green loop applications. In other words, different designs and configurations of boards, formwork, or containers are required for different types of applications. Thus, there is a need to have a universal container that can be used for different types of applications.

With the tray according to the invention, the above-mentioned and other problems are solved and progress in the art is made. The present invention relates to a multifunctional tray that can be used in a variety of applications to form different products such as a planter board for green roofing, a thermal insulation structure for a roof deck, a solid cement panel for building construction, and the like. The trays according to the invention are lightweight (about 1.5 kg) and can be used to form a modular structure consisting of a plurality of trays interlocked fixedly with one another. In addition, some unique features of the tray, such as having a partition and a fixed unit, improve the strength, stiffness, and robustness of the tray.

A tray according to an embodiment of the present invention includes a top portion, a bottom portion, and a backing layer connected between the top portion and the bottom portion. The lower portion includes a plurality of storage portions spaced thereunder across the backing layer. Each of the reservoirs includes an opening and a base defined through a backing layer, and the base has a plurality of protrusions adjacent to the through-hole and the through-hole allowing water to pass therethrough, Leaving a gap between the through-hole and the support surface.

The upper portion includes a sidewall extending upwardly from the peripheral edge of the backing layer to define a cavity for receiving the material, wherein the sidewall has a height defining a cavity capacity. The plurality of dividers extend upwardly from the backing layer to divide the backing layer into a plurality of partitions in the cavity, each partition including a certain number of storage units. Each divider has a height that is lower than the height of the side wall so that two layers of material having a first layer formed in the partition and a second layer formed over the first layer to the upper end of the sidewall can be formed in the upper portion . A plurality of fixed units is formed on the inner surface of the side wall and is configured to secure the material in the cavity to the side wall such that the material is prevented from separating from the inner surface of the side wall.

The tray further includes a plurality of interlocking units, each of which is formed on an outer surface of the sidewall so that a modular structure having a plurality of trays interlocked fixedly by the interlocking unit can be formed And to interlock the tray with another tray. A multi-direction channel is defined below the tray, which is a space defined by a backing layer, a reservoir, and a support surface on which the tray is mounted.

In some embodiments, the height of each of the dividers is one half of the height of the sidewall. The backing layer is divided into nine partitions. The plurality of storage units are arranged as an array that is evenly spaced. The tray is made of a high compressive strength material.

In some embodiments, each of the fixed units is a pair of elongate L-shaped brackets arranged to face one another on the inner surface of the side wall to form a rectangular hollow housing with slots.

In some embodiments, the first layer of the upper portion is filled with a water retention material and the second layer of the upper portion is filled with the planting medium.

In some embodiments, the first layer of the upper portion is filled with a heat insulating material and the second layer of the upper portion is filled with cement, mortar, or concrete.

In some embodiments, the first and second layers of the upper portion and the plurality of reservoirs of the lower portion are filled with cement, mortar, or concrete.

A modular construction according to an embodiment of the present invention includes a plurality of trays as described above wherein the trays are fixedly interlocked with each other by an interlocking unit. The first layer of each of the trays is filled with the water-containing material, and the second layer of each of the trays is filled with the planting medium.

A modular thermal insulation structure according to an embodiment of the present invention includes a plurality of trays as described above wherein the trays are fixedly interlocked with each other by an interlocking unit. The first layer of each of the trays is filled with a heat insulating material, and the second layer of each of the trays is filled with cement, mortar, or concrete.

A modular building structure according to an embodiment of the present invention includes a plurality of trays as described above wherein the trays are fixedly interlocked with each other by an interlocking unit. The first, second, and plurality of reservoirs of each tray are filled with cement, mortar, or concrete.

The above and other features and advantages of the multifunctional tray according to the present invention are explained in the following description of the preferred embodiments with reference to the following drawings.
1 illustrates a top view of a tray according to an embodiment of the present invention.
2 is a bottom view of the tray of Fig.
Figure 3 is a side view of the tray of Figure 1;
4 is an upper perspective view of the tray of Fig.
Figure 5 is a bottom perspective view of the tray of Figure 1;
FIG. 6A is a cross-sectional view of the tray of FIG. 1 with an entire tray including upper and lower portions filled with cement, mortar, and / or concrete, in accordance with an embodiment of the present invention.
FIG. 6B is a cross-sectional view of the tray of FIG. 1 with an upper portion of the tray filled with a layer of cement, mortar, and / or concrete over the first layer and a layer of thermal insulation material, in accordance with an embodiment of the present invention.
FIG. 6C illustrates a cross-sectional view of the tray of FIG. 1 wherein the upper portion of the tray is filled with a layer of water-borne material and a layer of planting media over the first layer, according to an embodiment of the present invention.

The present invention relates to a multifunctional tray that can be used in a variety of applications to form different products such as planter boards for green roofing, insulation panels for roof decks, solid cement panels for building construction and the like.

1 to 5 show a plan view, a bottom view, a side view, and a perspective view of a tray 100 according to an embodiment of the present invention. The tray 100 includes a lower portion 200, an upper portion 300 and a backing layer 400 connected between the lower portion 200 and the upper portion 300 (see FIG. 3). These three components are integrally formed as a single structure to perform the functions of the present invention. The tray 100 is made of a strong, high compressive strength material, such as polypropylene, polystyrene, metal, and the like. In one embodiment, the dimensions of the tray 100 are approximately 0.5 x 0.5 x 0.07 m (width x length x height) and can withstand high compression loads. Those skilled in the art will appreciate that the tray 100 can be formed in other suitable dimensions without departing from the invention.

The backing layer 400 is integrally connected with the lower portion 200 and the upper portion 300 and supports the load from the upper portion 300 together with the lower portion 200. In one embodiment, the backing layer 400 is a flat square plate having four identical sides of about 0.5 m. The size of the backing layer 400 is associated with the desired dimensions of the tray 100 and may be formed into any suitable shape (e.g., rectangular, hexagonal, etc.) and size without departing from the present invention.

The lower portion 200 includes a plurality of storage portions 201 spaced from each other across the backing layer 400. The lower portion 200 not only promotes air flow / circulation, but also assists collecting and draining. In one embodiment, the reservoirs 201 are arranged as an array evenly spaced across the backing layer 400 (see Figures 2 and 5). The reservoir 201 may also be arranged in other suitable patterns or configurations so long as the reservoir 201 is allowed to be continuously positioned on a relatively flat surface on which the tray 100 is mounted. Each of the reservoirs 201 should have a structure suitable for collecting such as a cup-shaped structure. In one embodiment, the cup-shaped reservoir 201 has a diameter of about 30 mm and a height of about 20 mm.

Each reservoir 201 has an opening 203 formed through the backing layer 400 so that moisture / material from the upper portion 300 can flow into the reservoir 201 through the opening 203. The storage unit 201 also has a base 205 (opposite the opening 203) through which the through hole 207 drains water from the storage unit 201, / ≪ / RTI > Thus, for example, when the tray 100 is used for planting plants, excessive moisture from the tray 100 collected by the storage unit 201 is discharged to the outside of the tray 100 through the through hole 207 It can be drained. Those skilled in the art will recognize that two or more through holes 207 may be formed in base 205 and / or other portions of storage 201 without departing from the invention. A plurality of small protrusions (or ribs or feet) 209 that can be arranged symmetrically adjacent to the rim of the through hole 207 are formed in the base 205 so that the tray 100 The protrusion 209 will come into contact with the support surface and leave a small gap (e.g., about 3 mm) between the opening of the through hole 207 and the support surface. This small gap assists in the drainage of water from the reservoir 201. In other words, the protrusion 209 prevents the through hole 207 from being blocked by the support surface on which the tray 100 is installed.

The top portion 300 includes side walls 301 that extend upwardly from the peripheral edge of the backing layer 400 to form a cavity for receiving the material. The height of the side wall 301 defines the capacity of the cavity and limits the amount of material that can be filled in the cavity. In one embodiment, the height of the side wall 301 is about 50 mm. A plurality of fixed units 303 are formed on the inner surface 305a of the sidewall 301 and the material (e.g., cement, mortar, and / or concrete) in the cavity is held and secured to the sidewalls 301, 301 is prevented from separating from the inner surface 305a. 4), each fixed unit 303 is a pair of elongated L-shaped brackets 307 and a slot 309 (i. E., Opposite to the inner surface 305a of the side wall 301) Are arranged to face each other on the inner surface 305a of the sidewall 301 to form a rectangular hollow housing having a rectangular, elongated opening. Both ends of the hollow housing are end-opened. For example, the cement is poured into the cavity so that the cavity and all hollow housing (fixed unit 303) along the inner surface 305a of the side wall 301 are filled with cement and formed integrally as a single cement body . Thus, when the cement is cured, the cement inside the hollow housing (connected to the cement in the cavity) will fix the cement in the cavity to the side wall 301 and the cement is separated from the inside surface 305a of the side wall 301 . This feature is particularly advantageous when the tray 100 is installed on an inclined surface where the material in the cavity will have a tendency to move toward the lower end of the incline and thereby break the side wall 301 at the lower end, Especially useful. Thus, the fixing unit 303 prevents the movement of the material in the cavity and thereby avoids the breakage of the side wall 301 of the tray 100 by the material.

The upper portion 300 further includes a plurality of dividers 311 extending upwardly from the backing layer 400 to divide the backing layer 400 into a plurality of partitions 312 for receiving material. In one embodiment, the upper portion 300 has nine identical sized partitions 312 (see Figures 1 and 4). Each partition 312 includes a certain number of reservoirs 201 of the lower portion 200, such as eight or nine reservoirs as shown in Figures 1 and 4. Each of the dividers 311 has a height that is lower than the height of the side wall 301. The height of each of the dividers 311 is preferably half the height of the side wall 301. In one embodiment, the height of each divider 311 is about 25 mm. The difference in height between the side wall 301 and the divider 311 allows the top portion 300 to be filled with two layers of material wherein the first layer 315 of the top portion 300 is partitioned 312 from the backing layer 400 to the upper end 317 of the divider 311 and the upper portion of the second layer 319 may be filled with the upper end of the side wall 301 321 may be filled with the second material on the first layer 315. The first and second layers 315, 319 may be the same or different materials, depending on the application of the tray 100. The presence of the partitions 312 in the lower portion of the upper portion 300 helps to improve the strength and stiffness of the tray 100 and thereby reduce the likelihood that the backing layer 400 will be fractured by the load. In addition, they serve to disperse the applied load and limit lateral movement of the material within the partition 312. [ A side gap 323 is provided between the inner surface 305a of the sidewall 301 and the adjacent divider 311 so that the first layer 315 of material is surrounded by the second layer 319 of material (Except for the bottom surface that contacts the backing layer 400).

A plurality of interlocking units 500 are formed in the outer surface 305b of the sidewall 301 for fixedly interlocking the tray 100 with the other trays. Accordingly, a modular structure composed of a plurality of trays 100 interlocked by the interlocking unit 500 can be formed. The interlocking unit 500 may be formed in any suitable configuration using a suitable interlocking mechanism. In one embodiment, the interlocking unit 500 is a slot-type connector comprised of a female connector 501 and a matching male connector 503 (Figs. 1, 2, 4, And Fig. 5).

A multi-direction water channel 510 is formed below the tray 100, which is a channel that allows the lower side water to flow to the drain portion in a different direction when the tray 100 is installed on a relatively flat surface. The water channel 510 is a space below the tray 100 defined by a backing layer 400, a storage unit 201, and a support surface on which the tray is installed. The width of each channel is equal to the distance between two adjacent reservoirs 201, such as 25 mm for example. The water channel 510 allows the excessive moisture on the underside of the tray 100 to flow quickly to the drain portion in a direction different from that of the tray 100 so that no water is trapped or accumulated under the tray 100 at all.

The tray 100 as described above is a multifunctional tray that can be used in various areas such as green roofing, roof deck insulation, building construction, and the like. Below, three different products using the tray 100 for different applications are presented. 6A illustrates an embodiment of a solid cement, mortar, and / or concrete panel 600 using trays 100 for building construction applications. In this embodiment, the entire tray 100, including the first layer 315 and the second layer 319 of the upper portion 300 and the plurality of reservoirs 201 of the lower portion 200, Mortar, and / or concrete 601 (with or without chemical additives). A modular structure including a plurality of solid panels 600 may be formed by fixedly interlocking the solid panel 600 with the interlocking unit 500.

6B illustrates an embodiment of a thermal insulation panel 610 using a tray 100 for a loop deck insulation application. In this embodiment, the partition 312 (i.e., the first layer 315) of the upper portion 300 is filled with a heat insulating material 611 and the first layer is made of cement, mortar, and / or concrete 613 ) (I.e., second layer 319) (with or without chemical additives). In this embodiment, the storage portion 201 of the lower portion 200 is not filled with any material. The insulating material 611 reduces the heat transfer from the roof deck to the underlying building. In one embodiment, the insulating material 611 is a polystyrene foam. A modular insulation structure including a plurality of insulation panels 600 can be formed by fixedly interlocking the insulation panels 610 with each other by the interlocking unit 500. [

6C illustrates an embodiment of a plant structure 620 using tray 100 for a green loop planting application. In this embodiment, the partition 312 (i.e., the first layer 315) of the upper portion 300 is filled with the water-containing material 621 and the first layer is the planting medium 623 Second layer 319). In this embodiment, the storage portion 201 of the lower portion 200 is not filled with any material. The water-containing material 623 can absorb moisture from the planting medium 623, temporarily store moisture, and allow excessive moisture to be released to the storage unit 201. [ In one embodiment, the water-containing material 621 is a polyurethane foam. The through hole 207 of the storage part 201 allows water to be drained out of the tray 100 and the water channel 510 prevents moisture buildup which may potentially cause water leakage on the roof deck. A modular plant structure including a plurality of plant structures 620 may be formed by fixedly interlocking plant structure 620 with interlocking unit 500.

Those skilled in the art will recognize that changes and / or modifications can be made to the invention as shown in the specific embodiments without departing from the spirit or scope of the invention as broadly described. Accordingly, the present embodiments are not to be considered in all respects as illustrative and not restrictive.

Claims (12)

As a tray,
A backing layer connected between the top portion and the bottom portion;
A plurality of interlocking units; And
And multi-direction channels formed on the lower side of the tray,
Wherein the lower portion comprises:
A plurality of reservoirs spaced beneath the backing layer, each reservoir including an opening and a base defined through the backing layer, the base having a through hole And a plurality of protrusions adjacent to the through-hole, the plurality of protrusions contacting a support surface on which the tray is mounted, leaving a gap between the through-hole and the support surface;
/ RTI >
Wherein the upper portion comprises:
A sidewall extending upwardly from a peripheral edge of the backing layer to define a cavity for receiving a material, the sidewall having a height defining a capacity of the cavity;
A plurality of dividers extending upwardly from the backing layer to divide the backing layer into a plurality of partitions within the cavity, each partition comprising a specific number of storage units, each of the dividers comprising: A height lower than a height of the sidewall such that two layers of material having a formed first layer and a second layer formed over the first layer to the upper end of the sidewall can be formed in the upper portion; And
A plurality of fixed units formed on an inner surface of the side wall and configured to secure the material in the cavity to the side wall such that the material is prevented from being separated from an inner surface of the side wall;
/ RTI >
The plurality of interlocking units are formed on an outer surface of the sidewall and are adapted to interlock the tray with another tray so that a modular structure having a plurality of trays interlocked fixedly by the interlocking units can be formed Respectively,
Wherein the multi-way channels are spaces defined by the backing layer, the storage portions, and the support surface on which the tray is installed. The method according to claim 1,
Wherein the height of each of the dividers is about half the height of the side wall. The method according to claim 1,
Wherein the backing layer is divided into nine partitions. The method according to claim 1,
Wherein the plurality of reservoirs are arranged as equally spaced arrays. The method according to claim 1,
Wherein said tray is made of a high compressive strength material. The method according to claim 1,
Each of said fixed units being a pair of elongate L-shaped brackets arranged to face one another on an inner surface of said side wall to form a rectangular hollow housing having slots. The method according to claim 1,
Wherein the first layer of the upper portion is filled with a water retention material and the second layer of the upper portion is filled with a planting medium. The method according to claim 1,
Wherein the first layer of the upper portion is filled with a heat insulating material and the second layer of the upper portion is filled with cement, mortar, or concrete,
tray. The method according to claim 1,
Wherein the first and second layers of the upper portion and the plurality of reservoirs of the lower portion are filled with cement, mortar, or concrete. As a modular plant structure,
A tray comprising a plurality of trays according to any one of claims 1 to 6,
Said trays being fixedly interlocked with each other by said interlocking units,
Wherein the first layer of each of the trays is filled with a water-
Wherein the second layer of each of the trays is filled with a planting medium. As a modular insulation structure,
A tray comprising a plurality of trays according to any one of claims 1 to 6,
Said trays being fixedly interlocked with each other by said interlocking units,
The first layer of each of the trays is filled with a heat insulating material,
Wherein the second layer of each of the trays is filled with cement, mortar, or concrete. As a modular building structure,
A tray comprising a plurality of trays according to any one of claims 1 to 6,
Said trays being fixedly interlocked with each other by said interlocking units,
A first layer, a second layer, and a plurality of reservoirs of each of the trays are filled with cement, mortar, or concrete.

Images